Electron transport through single conjugated organic molecules:Basis set effects in ab initio calculations

We investigate electron transport through single conjugated molecules-including benzenedithiol, oligophenylene ethynylenes of different lengths, and a ferrocene-containing molecule sandwiched between two gold electrodes with different contact structures-by using a single-particle Green function meth...

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Published in:The Journal of chemical physics 2007-10, Vol.127 (14), p.144107-144107-6
Main Authors: Ke, San-Huang, Baranger, Harold U., Yang, Weitao
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Language:English
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container_title The Journal of chemical physics
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creator Ke, San-Huang
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description We investigate electron transport through single conjugated molecules-including benzenedithiol, oligophenylene ethynylenes of different lengths, and a ferrocene-containing molecule sandwiched between two gold electrodes with different contact structures-by using a single-particle Green function method combined with density functional theory calculation. We focus on the effect of the basis set in the ab initio calculation. It is shown that the position of the Fermi energy in the transport gap is sensitive to the molecule-lead charge transfer which is affected by the size of basis set. This can dramatically change, by orders of magnitude, the conductance for long molecules, though the effect is only minor for short ones. A resonance around the Fermi energy tends to pin the position of the Fermi energy and suppress this effect. The result is discussed in comparison with experimental data.
doi_str_mv 10.1063/1.2770718
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title Electron transport through single conjugated organic molecules:Basis set effects in ab initio calculations
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